Lower limb intracast pressures generated by different types of immobilisation casts

Chaudhury, Salma; Hazlerigg, A; Vusirikala, Anuhya; Nguyen, Jonathan; Matthews, Stephen J.

doi:10.5312/wjo.v8.i2.170

Cited by 11 publications

(11 citation statements)

References 16 publications

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Section: Resultsmentioning

confidence: 99%

“…The pressure applied by an orthopedic cast should be minimized (under 30 mmHg) to prevent the constriction of blood flow. [32] Other thermoplastic casts have been shown to exert mean pressures of 31 ± 3 mmHg without occluding the microcirculation of the skin. [33] In our experiments, the pressure was measured as a function of time using a capacitive sensing sleeve worn on the wrist of the subject underneath the cast, containing two co-facially arranged electrodes of conductive silver fabric heat-bonded to the opposite sides of the red spacer knit (Figure 1c), which served as the compressible dielectric layer for the capacitive sensing mechanism.…”

Section: Pressural Safetymentioning

confidence: 99%

See 1 more Smart Citation

An Expanding Foam‐Fabric Orthopedic Cast

Root

Sánchez

Tracz

et al. 2022

Adv Materials Technologies

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Approximately 8 million orthopedic fractures are reported in the United States annually. [1] The most common form of medical treatment for pediatric patients with a long bone fracture, and some adult patients with nondisplaced fractures, is to immobilize and protect the limb during the healing process, typically using a cast molded from fiberglass or plaster. This approach requires the focused attention of a clinician during the processes of application and removal (≈20 min each session). [2] Casting also carries a risk of skin complications due to thermal injury or sharp cast edges, difficulty in monitoring swelling of soft tissue, and the need to keep the cast clean and dry in a typically noncompliant adolescent patient. [3] Moreover, the cast removal process is particularly problematic for pediatric populations, who are often distressed by (and in some cases injured by) the oscillatory saw used for cast removal. [4] The time and challenge of application, potential for iatrogenic injury and skin complications, as well as the costs associated with the application and removal of these casts offer significant potential for improvement using modern textile and soft robotic approaches. [5] The earliest examples of modern orthopedic casts were developed in the mid-19th century using cotton bandages containing plaster of Paris. [2] Although plaster of Paris still finds use in modern orthopedic practice for splinting purposes, knit fiberglass bandages impregnated with polyurethane were introduced in the 1970s as an alternative technology. Such fiberglass casts are more permeable to X-rays, weigh less, solidify faster, and are more durable than plaster casts. [2] They are, however more expensive and less malleable (not as easily molded during application) than plaster casts. [2] Fiberglass casts are often used as definitive treatment for pediatric fractures, requiring prolonged periods of immobilization. Their circumferential application makes skin monitoring difficult and may require cast valving using an oscillatory saw to allow for swelling. The process of cast valving, while reducing the risk of compartment syndrome (tissue damage caused by the blockage of circulation due to excessive pressure), also introduces the risk for the loss of fracture reduction. [6] Plaster casts are reserved for Traditional orthopedic casting strategies used in the treatment of fractured limbs, such as fiberglass and plaster-based tapes, suffer from several drawbacks, including technically challenging molding for application, occurrence of skin complications, and the requirement of a potentially hazardous oscillatory saw for removal, which is frightening for pediatric patients. This work presents the design and evaluation of a foam-fabric cast (FFC) to overcome these drawbacks by integrating strategies from soft materials engineering and functional apparel design. A fabric sleeve is designed to enable the reactive injection molding of a polymer foam and provide a form-fitting orthopedic cast for the human forearm-with sufficient mechanica...

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Section: Resultsmentioning

confidence: 99%

Section: Pressural Safetymentioning

confidence: 99%

An Expanding Foam‐Fabric Orthopedic Cast

Root

Sánchez

Tracz

et al. 2022

Adv Materials Technologies

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“…4 In particular, tightly applied dressings can increase the patient’s perception of pain especially in the acute setting secondary to swelling. 3 A study that analyzed patients who presented to the emergency department secondary to cast concerns concluded that 23% of visits were due to tight casts and another 10% were due to pain. 6 Furthermore, anecdotally in the senior author’s upper extremity practice, patients will sometimes complain of pain associated with tight splint dressings.…”

Section: Discussionmentioning

confidence: 99%

“…The implication is that the pain may be secondary to increased below-dressing pressure between the dressing and the patient's skin. 3 In the extreme circumstance, an especially rigid or noncompliant circumferential dressing will not accommodate severe swelling, resulting in skin necrosis or even limb-threatening compartment syndrome. 4 One method to reduce the below-dressing pressure under circumferential dressings is to split the dressing longitudinally.…”

Section: Introductionmentioning

confidence: 99%

Impact of Casting and Splinting Manipulations on Below-Dressing Pressures: An Experimental Model

Adapa

Goyal

2018

Hand (New York, N,Y.)

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“…Garfin et al, on the other hand, discovered that univalve splitting decreased cast pressure by 65%, whereas bivalve splitting reduced cast pressure by 47% and 33% in the anterior and posterior compartments, respectively [8]. The lower limb intercast pressures measured in backslab, full POP, split POP, fibreglass and split fibreglass were 47.05 ± 31.8, 72.28 ± 60.3, 17.15 ± 7.53, 82.73 ± 67.0 and 26.58 ± 21.33 mmHg, respectively [9]. In another study, Marson and Keenan found that POP and fibreglass had mean casting pressures of 61.10 and 30.35 mmHg respectively, thus, fibreglass casting produces significantly higher pressure than POP casts [10].…”

Section: Introductionmentioning

confidence: 97%

Shape memory polymer smart plaster for orthopaedic treatments

Jeewantha

Jayalath²,

Don³

et al. 2022

Smart Mater. Struct.

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Shape memory polymer (SMP) is a smart material that can respond to external stimuli and recover its permanent shape after being programmed. Researchers have been interested in SMPs for invasive biomedical applications, but there are many opportunities for non-invasive applications. Thus, in this study, a novel hybrid shape memory polymer nanocomposite smart plaster (SP) is synthesised for non-invasive orthopaedic fractured bone immobilisation. Due to its considerable structural properties, the SP for this study was synthesised with Bisphenol A epoxy, reinforced with E-glass fibres, its bioinspiration qualities were improved incorporating TiO2 nanoparticles. After that, the SP was preserved for three months under five different conditions. This was done to compare their environmental durability and usability for fractured bone immobilisation by analysing the resulting thermomechanical and shape memory properties. In addition, an Abaqus finite element model was developed and validated which can be used to optimise the design and geometrical parameters of the SP. The SP vitro performance was verified, demonstrating a lower limb leg cylindrical cast in less than 10 minutes. The SP at 50oC and two layers of cotton webril produced the optimum results, and the recorded maximum undercast temperature was less than 45oC, which was within the safe limit for human use. Furthermore, the undercast pressure did not surpass 30.2±5.2 mmHg, indicating that the results are equivalent to other bone immobilisation procedures. Therefore, the synthesised SP showed a promising approach to address existing orthopaedic fractured bone limb immobilisation challenges.

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Lower limb intracast pressures generated by different types of immobilisation casts

Cited by 11 publications

References 16 publications

An Expanding Foam‐Fabric Orthopedic Cast

An Expanding Foam‐Fabric Orthopedic Cast

Impact of Casting and Splinting Manipulations on Below-Dressing Pressures: An Experimental Model

Shape memory polymer smart plaster for orthopaedic treatments

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